WO2017111949A1 - Utilisation d'un dispositif de couplage pour réaliser des portes logiques quantiques - Google Patents

Utilisation d'un dispositif de couplage pour réaliser des portes logiques quantiques Download PDF

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Publication number
WO2017111949A1
WO2017111949A1 PCT/US2015/067416 US2015067416W WO2017111949A1 WO 2017111949 A1 WO2017111949 A1 WO 2017111949A1 US 2015067416 W US2015067416 W US 2015067416W WO 2017111949 A1 WO2017111949 A1 WO 2017111949A1
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Prior art keywords
coupler
qubit
quantum
operating frequency
control signal
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PCT/US2015/067416
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English (en)
Inventor
Chad T. RIGETTI
Eyob A. SETE
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Rigetti & Co., Inc.
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Priority to US15/121,483 priority Critical patent/US10056908B2/en
Priority to PCT/US2015/067416 priority patent/WO2017111949A1/fr
Publication of WO2017111949A1 publication Critical patent/WO2017111949A1/fr

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    • HELECTRICITY
    • H03ELECTRONIC CIRCUITRY
    • H03KPULSE TECHNIQUE
    • H03K19/00Logic circuits, i.e. having at least two inputs acting on one output; Inverting circuits
    • H03K19/02Logic circuits, i.e. having at least two inputs acting on one output; Inverting circuits using specified components
    • H03K19/195Logic circuits, i.e. having at least two inputs acting on one output; Inverting circuits using specified components using superconductive devices
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01RMEASURING ELECTRIC VARIABLES; MEASURING MAGNETIC VARIABLES
    • G01R33/00Arrangements or instruments for measuring magnetic variables
    • G01R33/02Measuring direction or magnitude of magnetic fields or magnetic flux
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F13/00Interconnection of, or transfer of information or other signals between, memories, input/output devices or central processing units
    • G06F13/38Information transfer, e.g. on bus
    • G06F13/40Bus structure
    • G06F13/4063Device-to-bus coupling
    • G06F13/4068Electrical coupling
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06NCOMPUTING ARRANGEMENTS BASED ON SPECIFIC COMPUTATIONAL MODELS
    • G06N10/00Quantum computing, i.e. information processing based on quantum-mechanical phenomena
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L9/00Cryptographic mechanisms or cryptographic arrangements for secret or secure communications; Network security protocols
    • H04L9/08Key distribution or management, e.g. generation, sharing or updating, of cryptographic keys or passwords
    • H04L9/0816Key establishment, i.e. cryptographic processes or cryptographic protocols whereby a shared secret becomes available to two or more parties, for subsequent use
    • H04L9/0852Quantum cryptography

Definitions

  • Quantum computers can perform computational tasks by executing quantum algorithms. Quantum algorithms are often expressed as a quantum circuit that operates on qubits. In some quantum computing architectures, the quantum circuits are implemented as a series of quantum logic gates, which may include single-qubit gates and two-qubit gates, for example. SUMMARY
  • a coupler device is used to perform a quantum logic gate in a quantum computing system. For example, a single-qubit gate or two-qubit gate may be performed.
  • a coupler operating frequency of the coupler device changes toward a qubit operating frequency of a qubit device, and a phase shift arises in a quantum state of the qubit device due to an interaction between the qubit device and the coupler device.
  • a coupler operating frequency of the coupler device in response to one or more coupler control signals received at a coupler device, changes toward a first qubit operating frequency of a first qubit device, and then changes toward a second qubit operating frequency of a second qubit device, and a controlled-phase shift arises in a quantum state of the first and second qubit devices due to interactions between the coupler device and the respective first and second qubit devices.
  • a coupler operating frequency of the coupler device in response to one or more coupler control signals received at a coupler device, is lowered toward a frequency corresponding to a joint excited state of two qubit devices, and a controlled- phase shift arises in a quantum state of the qubit devices due to interactions between the coupler device and the respective qubit devices.
  • FIG. 1 is a bock diagram of an example quantum computing system.
  • FIG. 2A is a block diagram showing devices and interactions in an example quantum computing system.
  • FIG. 2B shows an equivalent circuit for an example transmon qubit device.
  • FIG. 2C shows an equivalent circuit for an example fluxonium qubit device.
  • FIG. 2D shows an equivalent circuit for an example quantum computing system.
  • FIG. 3A is an energy level diagram for an example quantum computing system.
  • FIG. 3B is another energy level diagram for an example quantum computing system.
  • FIG. 4 is a plot of eigenfrequencies for an example quantum computing system.
  • FIG. 5A is a plot of operating frequencies in an example quantum computing system.
  • FIG. 5B is a plot of accumulated phases in an example quantum computing system.
  • FIG. 5C is a plot of state populations in an example quantum computing system.
  • FIG. 6 is a diagram of an example quantum logic circuit.
  • one or more quantum logic gates are performed.
  • the quantum logic gates form a subset of universal quantum gates for implementing quantum algorithms.
  • a set of single-qubit and two-qubit gates can form a universal set of quantum gates for implementing any quantum algorithm.
  • the gates can be used, for instance, in quantum computing systems to perform computational tasks.
  • the quantum logic gates can be performed with high fidelity, short gate operation time and easy tunability.
  • the quantum logic gates can be implemented to achieve a scalable quantum computing device.
  • techniques described here can provide the ability to generate single-qubit phase gates or two-qubit controlled-phase gates (or both) by applying a direct current (DC) pulse to a coupler device in a quantum processor cell.
  • DC direct current
  • These and other types of single-qubit gates or two-qubit gates may be performed with high accuracy using DC tuning, in some instances, without applying radio frequency (RF) or microwave pulses.
  • using DC pulses can simplify system requirements and reduce costs.
  • single-qubit phase gates or two-qubit controlled- phase gates (or both) can be performed quickly, with high fidelity and with easy tunability.
  • a coupler device can be tuned to control the coupling, the gate time, the gate fidelity or other metrics that can be used to characterize the quality of the gate.
  • the gate time can be on the order of 30-150 nanoseconds (ns) in length, with a fidelity above 0.99.
  • quantum logic gates can be implemented in a manner that provides scalability in a quantum computing architecture.
  • a qubit array can be formed by two or more types of qubit devices with distinct, fixed frequencies.
  • qubit devices that have fixed frequencies can allow long coherence times.
  • the techniques described here can be implemented in a manner that provides a high ON/OFF ratio for coupling between qubit devices. Other advantages or attributes may be achieved in various implementations of the subject matter described.
  • FIG. 1 is a schematic diagram of an example quantum computing system 100.
  • the example quantum computing system 100 shown in FIG. 1 includes a control system 110, a signal delivery system 106, and a quantum processor cell 102.
  • computing system may include additional or different features, and the components of a quantum computing system may operate as described with respect to FIG. 1 or in another manner.
  • the example quantum computing system 100 shown in FIG. 1 can perform quantum computational tasks by executing quantum algorithms.
  • the quantum computing system 100 can perform quantum computation by storing and manipulating information within individual quantum states of a composite quantum system.
  • qubits i.e., quantum bits
  • Coupler devices can be used to perform quantum logic operations on single qubits or conditional quantum logic operations on multiple qubits.
  • the conditional quantum logic can be performed in a manner that allows large-scale entanglement within the quantum computing device.
  • Control signals can manipulate the quantum states of individual qubits and the joint states of multiple qubits.
  • information can be read out from the composite quantum system by measuring the quantum states of the individual qubits.
  • the quantum computing system 100 can operate using gate-based models for quantum computing.
  • fault-tolerance can be achieved by applying a set of high-fidelity control and measurement operations to the qubits.
  • topological quantum error correction schemes can operate on a lattice of nearest-neighbor-coupled qubits.
  • these and other types of quantum error correcting schemes can be adapted for a two- or three-dimensional lattice of nearest- neighbor-coupled qubits, for example, to achieve fault-tolerant quantum computation.
  • the lattice can allow each qubit to be independently controlled and measured without introducing errors on other qubits in the lattice. Adjacent pairs of qubits in the lattice can be addressed, for example, with two-qubit gate operations that are capable of generating entanglement, independent of other pairs in the lattice.
  • the example quantum processor cell 102 shown in FIG. 1 includes qubit devices that are used to store and process quantum information. In some instances, all or part of the quantum processor cell 102 functions as a quantum processor, a quantum memory, or another type of subsystem.
  • the quantum processor cell 102 shown in FIG. 1 can be implemented, for example, as the quantum processor cell 204 shown in FIG. 2A or in another manner.
  • the qubit devices each store a single qubit (a bit of quantum information), and the qubits can collectively define the
  • the quantum processor cell 102 may also include readout devices that selectively interact with the qubit devices to detect their quantum states. For example, the readout devices may generate readout signals that indicate the computational state of the quantum processor or quantum memory.
  • the quantum processor cell 102 may also include coupler devices that selectively operate on individual qubits or pairs of qubits. For example, the coupler devices may produce entanglement or other multi-qubit states over two or more qubits in the quantum processor cell 102.
  • the example quantum processor cell 102 can process the quantum information stored in the qubits by applying control signals to the qubit devices or to the coupler devices housed in the quantum processor cell.
  • the control signals can be configured to encode information in the qubit devices, to process the information by performing logical gates or other types of operations, or to extract information from the qubit devices.
  • the operations can be expressed as single-qubit gates, two-qubit gates, or other types of logical gates that operate on one or more qubits.
  • a sequence of operations can be applied to the qubits to perform a quantum algorithm.
  • the quantum algorithm may correspond to a computational task, a quantum error correction procedure, a quantum state distillation procedure, or a combination of these and other types of operations.
  • the signal delivery system 106 provides communication between the control system 110 and the quantum processor cell 102.
  • the signal delivery system 106 can receive control signals (e.g., qubit control signals, readout control signals, coupler control signals, etc.) from the control system 110 and deliver the control signals to the quantum processor cell 102.
  • control signals e.g., qubit control signals, readout control signals, coupler control signals, etc.
  • the signal delivery system 106 performs preprocessing, signal conditioning, or other operations to the control signals before delivering them to the quantum processor cell 102.
  • control system 110 controls operation of the quantum processor cell 102.
  • the example control system 110 may include data processors, signal generators, interface components and other types of systems or subsystems.
  • control system 110 includes one or more classical computers or classical computing components.
  • FIG. 2A is a block diagram showing devices and interactions in an example quantum computing system 200.
  • the example quantum computing system 200 includes a control system 202 and a quantum processor cell 204.
  • the quantum computing system 200 may include additional or different features, and the components may be arranged in another manner.
  • the example quantum processor cell 204 includes a two-dimensional or three- dimensional device array, which includes coupler devices and qubit devices arranged in a lattice structure.
  • FIG. 2A shows five coupler devices 212A, 212B, 212C, 212D, 212E and four qubit devices 214A, 214B, 214C, 214D.
  • the coupler devices are implemented as fluxonium devices
  • the qubit device are implemented as transmon device.
  • the coupler devices and qubit devices may be implemented by other types of components.
  • the devices are arranged in a rectilinear (e.g., rectangular or square) array that extends in two spatial dimensions (in the plane of the page), and each coupler device has four nearest-neighbor qubit devices.
  • the devices can be arranged in another type of ordered array.
  • the rectilinear array also extends in a third spatial dimension (in/out of the page), for example, to form a cubic array or another type of three-dimensional array.
  • the quantum processor cell 204 may include additional devices, including additional qubit devices, coupler devices and other types of devices.
  • the control system 202 interfaces with the quantum processor cell 204 through a signal delivery system that includes connector hardware elements.
  • the control system connector hardware can include signal lines, signal processing hardware, filters, feedthrough devices (e.g., light-tight feedthroughs, etc.), and other types of components.
  • the control system connector hardware can span multiple different temperature and noise regimes.
  • the control system connector hardware can include a series of temperature stages (60 K, 3 K, 800 mK, 150 mK) that decrease between a higher temperature regime of the control system 202 and a lower temperature regime of the quantum processor cell 204.
  • the quantum processor cell 204 and in some cases all or part of the signal delivery system and connection hardware elements, can be maintained in a controlled cryogenic environment.
  • the environment can be provided, for example, by shielding equipment, cryogenic equipment, and other types of environmental control systems.
  • the components in the quantum processor cell 204 operate in a cryogenic temperature regime and are subject to very low electromagnetic and thermal noise.
  • magnetic shielding can be used to shield the system components from stray magnetic fields
  • optical shielding can be used to shield the system components from optical noise
  • thermal shielding and cryogenic equipment can be used to maintain the system components at controlled temperature, etc.
  • the example control system 202 shown in FIG. 2A may include, for example, a signal generator system, a program interface, a signal processor system and possibly other components.
  • components of the control system 202 can operate in a room temperature regime, an intermediate temperature regime, or both.
  • the control system 202 can be configured to operate at much higher temperatures and be subject to much higher levels of noise than are present in the environment of the quantum processor cell 204.
  • the quantum processor cell 204 can include an electromagnetic waveguide system that provides a low-noise electromagnetic
  • the electromagnetic waveguide system provides an environment for a lattice of devices (e.g., qubit devices, coupler devices, and possibly others).
  • the electromagnetic waveguide system includes apertures or other features that allow the delivery of signals to the lattice of qubits and to the coupler devices, and allow the extraction of readout signals from readout devices.
  • the coupler devices 212A, 212B, 212C, 212D, 212E are housed between neighboring pairs of the qubit devices 214A, 214B, 214C, 214D in a device array within the quantum processor cell 204.
  • the qubit devices can be controlled individually, for example, by delivering coupler control signals to the coupler devices.
  • the qubit devices can also interact with each other through the interactions with the coupler devices.
  • the interactions between neighboring qubit devices can be controlled, for example, by delivering coupler control signals to the individual coupler devices.
  • readout devices can detect the states of the qubit devices, for example, by interacting directly with the respective qubit devices.
  • the qubit devices 214A, 214B, 214C, 214D can each be encoded with a single bit of quantum information.
  • Each of the qubit devices has two eigenstates used as computational basis states ("0" and "1"), and each qubit device can transition between its computational basis states or exist in an arbitrary superposition of its basis states.
  • the quantum states of the respective qubit devices can be manipulated by coupler control signals generated by the control system 202.
  • the qubit devices are implemented by a charged-based qubit devices, such as, for example, the transmon qubit device shown in FIG. 2B. Other types of qubit devices may be used.
  • each qubit device in the quantum processor cell 204 has a fixed qubit operating frequency that is defined by an electronic circuit of the qubit device.
  • a qubit device e.g., a transmon qubit
  • the qubit operating frequency of a qubit device is tunable, for example, by application of an offset field.
  • a qubit device e.g., a fluxonium qubit
  • the coupler devices in the quantum processor cell 204 allow the qubits to be selectively coupled on-demand, to perform single-qubit gates, to perform multi-qubit gates, to entangle neighboring pairs of qubits, or to perform other types of operations.
  • the coupler devices can have a high "on/off" ratio, which refers to the ratio of the coupling rate provided by the coupler device when the coupler device is in its ON state versus its OFF state.
  • the coupler devices are implemented by a flux-based qubit, such as, for example, the fluxonium qubit device shown in FIG. 2C. Other types of coupler devices may be used.
  • each coupler device has a tunable coupler operating frequency.
  • the coupler operating frequency can be tuned by applying an offset field to the coupler device.
  • the offset field can be, for example, a magnetic bias field, a DC electrical voltage, or another type of constant field.
  • a coupler device may include a superconducting quantum interference device (SQUID) loop whose resonance frequency determines the coupling strength with each neighboring qubit device.
  • the coupling strength may be increased by setting the resonance frequency of the SQUID loop in a frequency range near the resonance frequency of either qubit device.
  • the resonance frequency of the SQUID loop can be tuned by controlling the amount of magnetic flux experienced by the SQUID loop.
  • manipulating the magnetic flux can increase or decrease the resonance frequency of the SQUID loop, which in turn influences the coupling strength provided by the coupler device.
  • the magnetic flux through the SQUID loop is an offset field that can be modified in order to tune the coupler resonance frequency.
  • the coupler device can include an inductor that is coupled to the SQUID loop by a mutual inductance.
  • the magnetic flux through the SQUID loop can be controlled by the DC component of the current through the inductor.
  • a coupling strength can be controlled by both AC and DC components of the coupler control signal.
  • coupler devices that are tunable by application of an offset field are used with qubit devices that do not respond to offset fields. This may allow the coupler devices to be selectively activated by an offset field that does not disturb the information encoded in the qubit device. For instance, although the offset field may cause the coupler device to produce an electromagnetic interaction between neighboring qubit devices, the offset field does not directly interact with the qubit device or disturb the quantum state of the qubit device even if the qubit device experiences the offset field.
  • the combination of tunable couplers with fixed-frequency qubit devices may allow selective, on-demand coupling of qubit devices while improving performance of the qubit devices. For example, the fixed-frequency qubit devices may have longer coherence times, may be more robust against environmental or applied offset fields, etc.
  • information is encoded in the qubit devices, and the information can be processed by operation of the coupler devices.
  • input information can be encoded in the computational states or computational subspaces defined by some of all of the qubit devices.
  • the information can be processed, for example, by applying a quantum algorithm or other operations to the input information.
  • the quantum algorithm may be decomposed as gates or instruction sets that are performed by the qubit devices and coupler devices over a series of clock cycles.
  • a quantum algorithm may be executed by a combination of single-qubit gates and two-qubit gates.
  • information is processed in another manner. Processing the information encoded in the qubit devices produces output information that can be extracted from the qubit devices.
  • the output information can be extracted, for example, by performing state tomography or individual readout operations. In some instances, the output information is extracted over multiple clock cycles or in parallel with the processing operations.
  • the control system 202 sends coupler control signals to the coupler devices in the quantum processor cell.
  • the coupler control signals can be configured to cause the coupler devices to change (increase or decrease) their respective coupler operating frequencies.
  • the coupler control signal can be a bias signal that varies an offset electromagnetic field experienced by the coupler device, and varying the offset electromagnetic field can change the resonance frequency of the coupler device.
  • the control signal can be a direct current (DC) electrical signal that is communicated from the control system 202 to the individual coupler device.
  • DC direct current
  • the example coupler control signals 206 shown in FIG. 2A are configured to change (e.g., increase, decrease) the coupler operating frequency of the coupler device 212C according to a control sequence.
  • a coupler control signals may be configured to tune the coupler device 212C according to the coupler operating frequency 310 shown in FIG. 3A, the coupler operating frequency 370 shown in FIG. 3B, the coupler operating frequency 436 shown in FIG. 4, the coupler operating frequency 512 shown in FIG. 5A, or another coupler operating frequency.
  • the control system 202 sends coupler control signals 206 to the coupler device 212C to generate interactions between the coupler device 212C and any of the nearest neighbor qubit devices.
  • the coupler control signals can generate a first interaction 216A between the coupler device 212C and the first qubit device 214A, a second interaction 216B between the coupler device 212C and the second qubit device 214B, a third interaction 216C between the coupler device 212C and the third qubit device 214C, a fourth interaction 216D between the coupler device 212C and the fourth qubit device 214D, or a combination of them in series or in parallel.
  • the coupler control signals are configured to generate interactions that perform quantum logic gates on the quantum states of one or more of the qubit devices.
  • the coupler device 212C in response to one or more of the coupler control signals 206, the coupler device 212C produces a phase shift in a quantum state of one of the neighboring qubit devices.
  • the coupler device 212C may produce a phase shift in a quantum state of the first qubit device 214A by the first interaction 216A between the first qubit device 214A and the coupler device 212C; the coupler device 212C may produce a phase shift in a quantum state of the second qubit device 214B by the second interaction 216B between the second qubit device 214B and the coupler device 212C; etc.
  • the coupler device 212C in response to one or more of the coupler control signals 206, the coupler device 212C produces a controlled-phase shift in a quantum state of two qubit devices.
  • the coupler device 212C may produce a controlled-phase shift in a quantum state of the first and second qubit devices 214A, 214B by the interactions (216A, 216B) between the coupler device 212C the respective first and second qubit device 214A, 214B; the coupler device 212C may produce a controlled-phase shift in a quantum state of the first and third qubit devices 214A, 214C by the interactions 216A, 216C between the coupler device 212C the respective first and third qubit device 214A, 214C; etc.
  • the coupler control signals 206 in FIG. 2A are configured to vary the coupler operating frequency of the coupler device 212C over a time period of the interactions that produce the phase shift or the controlled-phase shift.
  • the coupler operating frequency may increase during one or more portions the time period, decrease during one or more portions the time period, remain constant during one or more portions of the time period, in various combinations.
  • the rate and duration of increase or decrease can also be controlled.
  • the degree of phase shift produced, or the degree of controlled-phase shift produced is controlled by the attributes of the coupler control signals 206.
  • the phase acquired by the quantum state of the qubit can be controlled, at least in part, by a duration of the coupler control signal, an amplitude of the coupler control signal and possibly other attributes.
  • the controlled-phase acquired by the quantum state of the two qubits can be controlled, at least in part, by a duration of the coupler control signal, an amplitude of the coupler control signal and possibly other attributes.
  • the control system 202 generates a first coupler control signal that is configured to tune the coupler operating frequency of the coupler device 212C toward a first qubit operating frequency of the first qubit device 214A.
  • the first coupler control signal can be a DC electrical signal that lowers the coupler operating frequency toward a qubit operating frequency of the first qubit device 214A.
  • FIG. 3A An example is shown in FIG. 3A, where the coupler operating frequency 310 is lowered (at 312A) from a first frequency level 311 to a second frequency level 313. As shown in Fig. 3A, the coupler operating frequency 310 is then raised back to the first frequency level 311 after an interaction time at the second frequency level 313.
  • the first coupler control signal is communicated to the coupler device 212C to generate an interaction 216A that produces a phase shift in the quantum state of the qubit device.
  • the control system 202 after generating the first coupler control signal, the control system 202 generates a second coupler control signal that is configured to tune the coupler operating frequency of the coupler device 212C away from the first qubit operating frequency and toward a second qubit operating frequency of the second qubit device 214B.
  • the second coupler control signal can be a DC electrical signal that raises the coupler operating frequency toward a different qubit operating frequency.
  • FIG. 3A where the coupler operating frequency 310 is raised (at 314A) from the first frequency level 311 to a third frequency level 315. As shown in Fig. 3A, the coupler operating frequency 310 is lowered back to the first frequency level 311 after an
  • the first and second coupler control signals are communicated to the coupler device 212C in series to generate interactions 216A, 216B that produce a controlled-phase shift in the quantum state of the first and second qubit devices 214A, 214B.
  • the control system 202 generates a coupler control signal that is configured to lower the coupler operating frequency of the coupler device 212C toward a joint excited state of the first and second qubit devices 214A, 214B.
  • the first coupler control signal can be a DC electrical signal that lowers the coupler operating frequency toward the frequency of the joint excited state of the two qubits.
  • FIG. 3B An example is shown in FIG. 3B, where the coupler operating frequency 370 is lowered (at 372A) from a first frequency level 371 to a second frequency level 374. As shown in Fig. 3B, the coupler operating frequency 370 is raised back to the first frequency level 371 after an interaction time at the second frequency level 374.
  • the first coupler control signal is communicated to the coupler device 212C to generate interactions 216A, 216B that produce a controlled-phase shift in the joint quantum state of the first and second qubit devices 214A, 214B.
  • the coupler operating frequency is maintained higher than the frequencies of the two-photon states of the respective first and second qubit devices during the interactions.
  • FIGS. 2B, 2C and 2D show aspects of example devices that may be included in the quantum processor cell 204.
  • the quantum processor cell 204 may include additional or different types of devices.
  • the qubit devices and coupler device in the quantum processor cell 204 may be implemented as charge qubit devices, flux qubit devices or other types of devices.
  • the qubit devices 214A, 214B, 214C, 214D can be implemented as transmon qubit devices, and the coupler devices 212A, 212B, 212C, 212D, 212E can be implemented as fluxonium qubit devices.
  • the qubit devices 214A, 214B, 214C, 214D can be implemented as fluxonium qubit devices.
  • FIG. 2B shows an equivalent circuit 222 for an example transmon qubit device.
  • the transmon qubit device represented in FIG. 2B is an example of a charge qubit device.
  • a transmon qubit device can be fabricated on a substrate (e.g., formed from sapphire, silicon, etc.) that supports a superconducting thin film (e.g., formed from aluminum, niobium, etc.).
  • the transmon qubit device may be fabricated by double-angle evaporation of thin-film aluminum onto a sapphire or silicon substrate, or by another fabrication process.
  • the example transmon qubit device shown in FIG. 2B includes a Josephson junction 230 and a shunt capacitance 234.
  • the shunt capacitance 234 is formed in a topologically closed manner to reduce far-field coupling and spurious qubit couplings to non-adjacent couplers and non-neighboring qubits.
  • the example transmon device can be coupled to another device or an electrode, for example, by a differential capacitance 232 formed between the other device and inner and outer electrodes of the Josephson junction 230. [0057] FIG.
  • FIG. 2C shows an equivalent circuit 224 for an example fluxonium qubit device.
  • the fluxonium qubit device represented in FIG. 2C is an example of a flux qubit device.
  • a fluxonium qubit device can be fabricated on a substrate (e.g., formed from sapphire, silicon, etc.) that supports a superconducting thin film (e.g., formed from aluminum, niobium, etc.).
  • the fluxonium qubit device may be fabricated by double-angle evaporation of thin-film aluminum onto a sapphire or silicon substrate, or by another fabrication process.
  • a magnetic flux signal 246 can be applied to the loop.
  • the magnetic flux signal 246 can be applied to the loop, for example, by applying a DC signal to bias circuitry that has a mutual inductance with the loop.
  • the magnetic flux signal 246 can be, for instance, by a coupler control signal communicated to the bias circuitry.
  • the input capacitance 242 across the Josephson junction 240 can provide a charge- coupling control port.
  • the charge-coupling control port may be formed of a topologically closed capacitance, for instance, where an inner island is encircled by an outer island.
  • a control or coupling port can be realized by coupling the device with a differential capacitance with respect to these two islands to a nearby electrode.
  • FIG. 2D shows an equivalent circuit 250 for an example quantum computing system.
  • the devices represented in FIG. 2D are arranged in a device array or another type of ordered structure.
  • the equivalent circuit 250 in FIG. 2D can represent any of the coupler devices and its two nearest-neighbor qubit devices in the quantum processor cell 204 in FIG. 2A, or the equivalent circuit 250 in FIG. 2D can represent devices in another type of system or environment.
  • the example quantum computing system represented in FIG. 2D includes a first qubit device 252A, a second qubit device 252B, a coupler device 254 and a control port 256.
  • the quantum computing system may include additional or different features, and the components may be arranged as shown or in another manner.
  • the first and second qubit devices 252A, 252B are implemented as transmon qubit devices.
  • the qubit device circuitry includes a Josephson junction (represented by the symbol "X" in FIG. 2D) and a shunt capacitance.
  • the coupler device 254 includes a fluxonium qubit device and bias control circuitry.
  • the fluxonium device circuitry includes a Josephson junction, a shunt inductance and a shunt capacitance.
  • the bias circuitry includes an inductance loop that is connected to the control port 256 to receive coupler control signals.
  • Both of the qubit devices 252A, 252B are capacitively coupled to the coupler device 254 by respective differential capacitances 258A, 258B.
  • the qubit devices and coupler devices may be implemented by other types of systems, and the features and components represented in FIG. 2D can be extended in a larger two-dimensional or three-dimensional array of devices.
  • the tunable coupler device 254 includes bias circuitry that is coupled to the coupler control input port 256 to receive coupler control signals.
  • the bias circuitry in the example coupler device 254 is configured to apply an offset field to the fluxonium device circuitry.
  • the bias circuitry includes an inductor that has a mutual inductance with the fluxonium device circuitry.
  • the resonance frequency of the fluxonium device circuitry is the coupler operating frequency of the example coupler device 254, and the magnetic flux generated by the bias circuitry controls the resonance frequency of the fluxonium qubit device.
  • the coupler operating frequency of the coupler device 254 can change (increase or decrease) in response to a coupler control signal received by the bias circuitry through the control port 256.
  • the coupler operating frequency may be increased or decreased to a frequency range near the resonance frequency of either qubit device 252A, 252B.
  • the resonance frequency of the coupler circuitry can be tuned by controlling the amount of magnetic flux experienced by the fluxonium device circuitry.
  • manipulating the magnetic flux can increase or decrease the resonance frequency of the fluxonium device circuitry, which in turn influences the coupler operating frequency of the coupler device 254.
  • the magnetic flux through the coupler circuitry can be controlled by the DC component of the current through the inductor.
  • the coupler operating frequency is controlled in another manner, for instance, by another type of coupler control signal.
  • the example quantum computing system shown in FIG. 2D can apply single- qubit gates to the quantum state of either qubit device 252A, 252B, as well as two-qubit gates to the collective quantum state of the qubit devices 252A, 252B. As shown in FIG.
  • the parameter g lc represents the coupling strength between the first qubit device 252A and the coupler device 254, and the parameter g 2c represents the coupling strength between the second qubit device 252A and the coupler device 254.
  • the two qubit devices 252A, 252B have fixed qubit operating frequencies ⁇ 1 and ⁇ 2 , respectively, while the coupler device 254 has a tunable coupler operating frequency oo c (t) that changes over time.
  • the tunability of the coupler operating frequency can be used to generate single-qubit phase gates and two-qubit controlled-phase gates on the qubit devices 252A, 252B. For instance, by tuning the coupler operating frequency close to either of the qubit operating frequencies, a phase interaction can be generated between the two qubit devices 252A, 252B to produce the single-qubit or two-qubit quantum logic gates.
  • H ⁇ 1 ⁇ 1 + ⁇ 2 ⁇ 2 ⁇ ⁇ 2 + ⁇ ( ⁇ ) ⁇ ⁇ 3 + g lc a lx ⁇ g) ⁇ 3 ⁇ + g 2c a 2x ⁇ g) ⁇ 3 ⁇ .
  • ⁇ [ are the Pauli operators for the qubit devices 252A, 252B and the couple device 254.
  • fjO the computational basis
  • the one-qubit phase gate can be represented in the following general matrix form where ⁇ is the phase acquired by the state 11) of the qubit device to which the gate is applied during the gate operation.
  • the two-qubit controlled phase gate or single-qubit phase gate can be represented in the following general matrix form
  • ⁇ 01 , ⁇ 10 , and ⁇ 1 are the phases acquired by the states
  • a two-qubit controlled-phase gate or single-qubit phase gate can be performed in the example quantum computing system shown in FIG. 2D based on the techniques described with respect to FIGS. 3A, 3B, 4, 5A, 5B and 5C, or quantum logic gates may be performed in another manner.
  • FIG. 3A is an energy level diagram 300 for the example quantum computing system represented in FIG. 2D.
  • the example quantum computing system shown in FIG. 2D is described by the parameter values shown in Table I.
  • the example energy level diagram 300 shown in FIG. 3A includes four energy levels 302, 304A, 306A and 308 for the first and second qubit devices 252A, 252B.
  • the first energy level 302 corresponds to the quantum state 100), where the qubit devices 252A, 252B are in their respective ground states.
  • the second energy level 304A corresponds to the quantum state 110), where the first qubit device 252A is in its first excited state and the second qubit device 252B is in its ground state.
  • the third energy level 306A corresponds to the quantum state 101), where the first qubit device 252A is in its ground state and the second qubit device 252B is in its first excited state.
  • the fourth energy level 308 corresponds to the quantum state 101
  • the example energy level diagram 300 also shows the energy level
  • the example coupler operating frequency 310 changes over time as shown from left to right in FIG. 3A.
  • the coupler operating frequency begins at a "park" position, which is a first frequency level 311 approximately halfway between the first qubit operating frequency (corresponding to the energy level 304A) and the second qubit operating frequency (corresponding to the energy level 306A).
  • One or more coupler control signals can be communicated to the coupler device 254 to tune the coupler operating frequency 310 as shown in FIG. 3A and generate one or more interactions that perform a quantum logic gate on one or both qubit devices 252A, 252B.
  • the coupler operating frequency 310 can be decreased toward the first qubit operating frequency (corresponding to the energy level 304A) to perform a phase gate on the first qubit device 252A.
  • the coupler operating frequency decreases at 312A from the first frequency level 311 toward the first qubit operating frequency 304A.
  • the coupler operating frequency 310 is maintained at a second frequency level 313 near the first qubit operating frequency 304A.
  • an interaction between the coupler device 254 and the first qubit device 252A causes an energy level repulsion, represented by the shifted energy level 304B of the first qubit device 252A shown in FIG. 3A.
  • the coupler operating frequency then increases at 312B from the second frequency level 313 away from the first qubit operating frequency 306A. After increasing at 312 B, the coupler operating frequency 310 is maintained at the "park" position, which is the first frequency level 311. In some cases, a DC pulse or another type of coupler control signal received at the coupler device 254 causes the coupler operating frequency 310 to change as shown in FIG. 3A and described above.
  • the coupler operating frequency 310 can be increased toward the second qubit operating frequency (corresponding to the energy level 306A) to perform a phase gate on the second qubit device 252B.
  • the coupler operating frequency increases at 314A from the first frequency level 311 toward the second qubit operating frequency 306A.
  • the coupler operating frequency 310 is maintained at a third frequency level 315 near the second qubit operating frequency 306A.
  • an interaction between the coupler device 254 and the second qubit device 252B causes an energy level repulsion
  • the coupler operating frequency then decreases at 314B from the third frequency level 315 away from the second qubit operating frequency 306A. After decreasing at 314B, the coupler operating frequency 310 is maintained at the "park" position, which is the first frequency level 311.
  • a DC pulse or another type of coupler control signal received at the coupler device 254 causes the coupler operating frequency 310 to change as shown in FIG. 3A and described above.
  • the example quantum computing system shown in FIG. 2D when the frequency of the coupler device 254 is tuned close the frequency of either qubit device 252A, 252B, an energy level repulsion (due to the AC Stark shift) is generated. This level repulsion gives rise to a phase in the quantum state of the qubit device, thus generating a single-qubit phase gate in some instances. Accordingly, the example quantum computing system shown in FIG. 2D can generate single-qubit gates on the first qubit device 252A by applying a single pulse, for instance, tuning the coupler operating frequency of the coupler device 254 from its park position (e.g., the first frequency level 311) toward the first qubit operating frequency 304A; or the example quantum computing system shown in FIG.
  • a single pulse for instance, tuning the coupler operating frequency of the coupler device 254 from its park position (e.g., the first frequency level 311) toward the first qubit operating frequency 304A; or the example quantum computing system shown in FIG.
  • 2D can generate single-qubit gates on the second qubit device 252B by applying a single pulse, for instance, tuning the coupler operating frequency of the coupler device 254 from its park position (e.g., the first frequency level 311) toward the second qubit operating frequency 306A.
  • the coupler device 254 is maintained in its ground state during the gate operations, so that leakage to the coupler device 254 is avoided, minimized or otherwise reduced.
  • the coupler operating frequency is controlled by one or more coupler control signal that are communicated to the coupler device 254 from the control system 202.
  • the phase shift produced by the single-qubit gate can be controlled, at least in part, by a duration of the coupler control signal and an amplitude of the coupler control signal.
  • the amplitude of the coupler control signal can control the amplitude of the coupler operating frequency
  • the duration of the coupler control signal can control the duration of the interaction.
  • the coupler control signal is configured to vary the coupler operating frequency over a time period of the coupler control signal, and the coupler operating frequency is increased, decreased, or held at a constant level during various portions of the time period according to the coupler control signal.
  • the coupler control signal can be configured to generate one or more interactions that produce a phase shift
  • t represents the time period of the interactions
  • g represents a coupling strength between the coupler device and the qubit device
  • A(t') represents a difference between the coupler operating frequency and the qubit operating frequency
  • 2D can generate two-qubit gates on the first and second qubit devices 252A, 252B by applying a sequence of pulses, for instance, tuning the coupler operating frequency of the coupler device 254 from its park position (e.g., the first frequency level 311) toward the first qubit operating frequency 304A, back to its park position, and then toward the second qubit operating frequency 306A.
  • the quantum state of the first qubit device 252 A acquires a significant phase shift determined by the coupling strength g lc and the frequency difference A lc
  • the second qubit device 252B may also acquire a small phase shift due to its interaction with the coupler device 254 at the park frequency.
  • the second qubit device 252B acquires a significant phase shift determined by the coupling strength g 2c and the frequency difference A 2c , and the first qubit device 252A may also acquire a small phase shift due to its interaction with the coupler device 254 at the park frequency.
  • the coupler operating frequency is controlled by one or more coupler control signals that are communicated to the coupler device 254 from the control system 202.
  • the controlled-phase shift i.e., the state- dependent phase shift
  • the amplitude of the coupler control signal can control the amplitude of the coupler operating frequency
  • the duration of the coupler control signal can control the duration of the interaction.
  • each coupler control signal is configured to vary the coupler operating frequency over a time period of the coupler control signal, and the coupler operating frequency is increased, decreased, or held at a constant level during various portions of the time period according to the coupler control signal.
  • the coupler control signal can be configured to generate one or more
  • t represents the time period of the interactions
  • g lc represents a coupling strength between the coupler device 254 and the first qubit device 252A
  • g 2c represents a coupling strength between the coupler device 254 and the second qubit device 252B
  • a lc (t') represents a difference between the coupler operating frequency 310 and the first qubit operating frequency 304A
  • a 2c (t') represents a difference between the coupler operating frequency 310 and the second qubit operating frequency 306A.
  • phase shift of each quantum state of the two-qubit system can be computed based on the example shown in FIG. 3A.
  • the net phase shifts acquired by the two-qubit states are given by
  • FIG. 3B is another energy level diagram 350 for the example quantum computing system represented in FIG. 2D.
  • the example energy level diagram 350 shown in FIG. 3B includes six energy levels 352, 354, 356, 358, 360 and 362 for the first and second qubit devices 252A, 252B and the coupler device 254.
  • the quantum state of the coupler device 254 is represented by the third position in each ket, and three energy levels of the qubit devices 252A, 252B are represented.
  • the coupler operating frequency 370 is lowered toward the frequency of the joint excited state of the two qubit devices 252A, 252B to perform a controlled-phase gate on the first and second qubit devices 252A, 252B.
  • the coupler operating frequency 370 initially decreases at 372A from the first frequency level 371 toward the joint excited state level 362.
  • the coupler operating frequency 370 is maintained at a second frequency level 374 near the joint excited state level 362.
  • the coupler operating frequency 436 is tuned to a second frequency level 442 (at or near 3.4 GHz) and then back to the park frequency; the coupler operating frequency 436 is then tuned to a third frequency level 444 (at or near 5 GHz) and then back to the park frequency.
  • the phase shifts acquired by the two-qubit states are as follows

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Abstract

Dans un aspect général, une porte logique quantique peut être réalisée en ajustant un dispositif de couplage. Un ou plusieurs signaux de commande de coupleur peuvent être reçus sur un dispositif de couplage dans une cellule de processeur quantique. Dans certains cas, en réponse aux signaux de commande du coupleur, une fréquence de fonctionnement de coupleur du dispositif de couplage commute vers une fréquence de fonctionnement qubit d'un dispositif qubit, et un déphasage survient dans un état quantique du dispositif qubit en raison d'une interaction entre le dispositif qubit et le dispositif de couplage. Dans certains cas, en réponse aux signaux de commande, la fréquence de fonctionnement de coupleur commute vers une première fréquence de fonctionnement qubit d'un premier dispositif qubit, puis commute vers une seconde fréquence de fonctionnement qubit d'un second dispositif qubit, et un déphasage contrôlé survient dans un état quantique des dispositifs qubit en raison des interactions entre le dispositif de couplage et les dispositifs qubit respectifs.
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